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A new startup venture in Quantum Computing

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Provision of Quantum Computing (QC) server farms to provide researchers in pure math and applied science fields access to QC devices able to be programmed in Python with data input and returned via the internet.

Quantum Computing Using Photonic Hardware

The theory of Quantum Computing has developed to the stage where physical devices are now being built.

It is important to note for all investors and interested parties that this proposed photonic computer design is NOT claiming to be a fully fledged quantum computer in the strict terms of the QC definition further research is required once the first photonic single qubit general purpose quantum logic gate device is constructed and tested.

Light as the vehicle for Qubit manipulation required for Quantum Computational tasks has some major benefits, but pure mathematical theory development and significant technical issues need to be overcome.

The benefits are that extreme isolation and cryogenic techniques are not required to protect the data from noise as the photon is a complete electromagnetic data packet, that is more robust than the nanometer electric or magnetic energy packets currently being used in current Quantum computer research.

The technical issues require a mathematical re-examination of the Qubit which arbitrarily only uses the real number property and ignores the imaginary number part of the complex number. It is this authors theory that the Qubit can be more accurately described as a Quaternion with two axis of freedom on the Bloch sphere.

The technical issues involve nano-technology and providing an on demand supply of single photon streams.

This new venture proposes to use the Quantum effect known as metastability in a simple RS Flip Flop circuit to represent a Qubit as a Quaternion with two degrees of freedom in a Qubit Register.

Initial research used a FET based Flip Flop data latch that can be switched between a known state and an unknown quantum state (as a free running multivibrator) in order to input data initially as a conventional electrical binary signal and convert it an electro-magnetic (light) signal via diode lasers data stream.

The Quantum Computation happens within a photonic chip where the the two input streams of single photons are used to pump nanometre sized areas within the YAG wafer in order to output a third stream of photons from the top face of the square YAG wafer to produce an interference pattern in the Infra Red spectrum that is analysed using an infra red megapixel sized CCD or CMOS retina device.

The first Operand stream we will call the Alice (A) operand and the second operand Bob (B). The Alice operand will be the initial data state. The Bob operand can be cycled as a fixed bit mask or rapidly toggling stream as required to form a multi-purpose quantum logic gate. Both the Bob and Alice operand can be toggled from a known data state to a rapidly changing data stream.

The initial prototype will have 64 bits in each register to represent 32 Q and 32 NotQ of data to match the current 32 bit data structure of the IPv4 internet protocol. The development pathway will be the provision of 256 bit's per register to code 128 Qubits for the data packet size of the new IPv6 internet protocol.

This new device is envisioned to be a training and research tool to allow programmers and researcher's a platform to interface with the proposed photonic QC with the Python programming language. A secure server room will house hundreds of these devices which can be coupled into massive parrallel computing resources or single servers.

It is envisioned that the first working devices will be the provision of a secure Network of QC photonic server devices hosted in Australia.